TY - JOUR T1 - A new improved and extended version of the multicell bacterial simulator <kbd>gro</kbd> JF - bioRxiv DO - 10.1101/097444 SP - 097444 AU - Martín Eduardo Gutiérrez AU - Paula Gregorio-Godoy AU - Guillermo Pérez del Pulgar AU - Luis Muñoz AU - Sandra Sáez AU - Alfonso Rodríguez-Patón Y1 - 2016/01/01 UR - http://biorxiv.org/content/early/2016/12/30/097444.abstract N2 - gro is a cell programming language developed in Klavins Lab for simulating colony growth and cell-cell communication. It is used as a synthetic biology prototyping tool for simulating multicellular biocircuits. In this work, we present several extensions made to gro that improve the performance of the simulator, make it easier to use and provide new functionalities. The new version of gro is between one and two orders of magnitude faster than the original version. It is able to grow microbial colonies with up to 105 cells in less than 20 minutes. A new library, CellEngine, accelerates the resolution of spatial physical interactions between growing and dividing cells by implementing a new shoving algorithm. A genetic library, CellPro, based on Probabilistic Timed Automata, simulates gene expression dynamics using simplified and easy to compute digital proteins. We also propose a more convenient language specification layer, ProSpec, based on the idea that proteins drive cell behavior. CellNutrient, another library, implements Monod-based growth and nutrient uptake functionalities. The intercellular signaling management was improved and extended in a library called CellSignals. Finally, bacterial conjugation, another local cell-cell communication process, was added to the simulator. To show the versatility and potential outreach of this version of gro, we provide studies and novel examples ranging from synthetic biology to evolutionary microbiology. We believe that the upgrades implemented for gro have made it into a powerful and fast prototyping tool capable of simulating a large variety of systems and synthetic biology designs. ER -